纵火现场中汽油、煤油和柴油残留物的ATD／GC／MS法检测

目的为火场中汽油、煤油和柴油残留物的检测建立一种简便、高灵敏度的ATD／GC／MS检验方法。方法采用Tenax TA吸附管吸附富集检材中的汽油、煤油和柴油成分。然后用美国PE公司的ATD／GC／MS仪器进行全自动的解吸和分析检测。结果检材中汽油、煤油和柴油的检测极限分别达0．05、0.2、0．2pL／mL。结论该方法具解吸和分析检测过程自动化。操作简便快捷，检测灵敏度高。杂质干扰少等特点，可用于实际火场皆汽油、煤油和柴油残留物的检测。     

GC/MS/MS时间编程在火灾现场助燃剂检测中的应用

运用Varian SATURN2000气质联用仪通过GC/MS、GC/MS/MS、时间编程 GC/MS/MS对汽油样品进行分析比对,发现利用时间编程GC/MS/MS,对检测火灾现场残留汽油效果很好,可彻底排除样品中基体的背景干扰,大大提高检测灵敏度;同时对混合助燃剂（汽油+煤油、汽油+柴油）进行了实验探索。     

中空纤维液相微萃取-气质联用检测血液中的三唑仑

目的建立中空纤维膜液相微萃取-气质联用测定血液中三唑仑的方法。方法取2mL全血用pH9缓冲溶液稀释至10mL制成样品溶液,采用中空纤维膜进行液相微萃取,直接抽取中空纤维内腔中的有机溶剂进行GC/MS分析。考察和选择最优萃取条件,包括中空纤维长度、萃取剂、萃取温度、搅拌速率、萃取时间,并进行方法学评价。结果最优萃取条件为:5cm长中空纤维,萃取剂为辛醇,萃取温度为30℃,搅拌速率为600r/min,萃取时间为30min。方法学评价表明线性范围为0.1~10.0μg/mL(r=0.999 0),相对标准偏差在0.8%~2.5%,检测限为72.8ng/mL,回收率为74%,富集倍数为165。结论本文方法萃取和浓缩一步完成,简便、快速、消耗有机溶剂少,重现性好,可在血液三唑仑药物检测中选用。     

固相微萃取与气相色谱仪联用技术在火场助燃剂检验中的应用

目的建立检验纵火案件现场燃烧残留物中助燃剂的一种方法。方法利用固相微萃取器吸附浓缩燃烧残留物中的挥发性气体,使用气相色谱仪对挥发性气体进行定性分析。结果固相微萃取与气相色谱仪联用能较好地对火场不同介质燃烧残留物中汽油、煤油、柴油等助燃剂进行种类认定。结论该方法简便易行。     

液相微萃取-气相色谱法检测尿液中三唑仑药物

目的建立液相微萃取与气相色谱联用技术快速分析尿液中三唑仑的方法。方法本方法考察了萃取溶剂、体积、萃取时间、萃取振荡速度等条件对液相微萃取的影响,优化的实验条件为:萃取溶剂为0.5ml三氯甲烷,萃取时间25min,振荡速度200r/min。结果采用本文所建立的方法,三唑仑回收率为88.0%~90.5%。结论实验结果表明该方法简便、快速、灵敏、消耗有机溶剂少,是尿液中三唑仑检测的一种有效方法。     

固相微萃取-气相色谱质谱法测定血浆中的氯氮平浓度

目的建立固相微萃取-气相色谱质谱法测定人血浆中氯氮平浓度的方法。方法以固相微萃取法提取血浆中的氯氮平,萃取头为100μm聚二甲基硅氧烷,洛沙平作内标,用气相色谱质谱选择离子法进行检测。结果本文建立的方法在5~2000 ng/ml浓度范围内呈线性关系,检测限为0.1 ng/ml(信噪比>3),低、中、高浓度(100、500、1000 ng/ml)平均相对回收率分别为98.6%、94.6%和94.6%,日内、日间RSD分别小于7.4%和7.1%。结论本文建立的固相微萃取-气相色谱质谱法灵敏度高、准确度好、操作简便,适用于氯氮平急性中毒案件的检测。     

SPME—GC／MS／MS法分析血中助燃剂残留物

目的探讨检验血中助燃剂残留物的分析方法。方法运用SPME(固相微萃取)技术,利用100μmPDMS萃取纤维,于室温条件下以顶空方式直接从血中萃取、浓缩挥发性碳氢化合物,用GC/MS/MS检测分析助燃剂。结果从检验的实际案例显示,可从0.1ml血中检出痕量的助燃剂。结论该方法操作时间短,检材用量少,分析结果较理想。     

体液中氟乙酰胺SPE-GC/MS检测

目的　利用GC/MS与固相萃取 (SPE)技术相结合 ,开发血和尿样中氟乙酰胺鼠药的GC/MS定量分析新方法 ,并用于实际案例检测。方法　选择乙酰胺为内标 ,通过比较不同固相柱的萃取效率和不同条件对回收率的影响 ,优化用于血和尿样中氟乙酰胺萃取的固相柱和提取条件 ,利用氟乙酰胺与乙酰胺质谱图的分子离子峰面积之比与氟乙酰胺浓度的定量关系 ,建立血和尿样中氟乙酰胺鼠药的GC/MS定量分析新方法。结果　用硅胶柱萃取 ,峰面积之比与氟乙酰胺浓度在 5 0～ 90 μg/ml范围呈线性关系 ,检测限为 1 0 μg/ml。血样中氟乙酰胺检测的平均回收率达 91 6% ,标准偏差小于 7 3 %。结论　此法对实际样品的测定证明可满足氟乙酰胺鼠药中毒的定性定量要求。     

血液、脑脊液中尼可刹米的HPLC法分析

目的建立血液、脑脊液中尼可刹米的HPLC检测方法。方法取空白血液或脑脊液添加不同量的尼可刹米对照液,碱化后用二氯甲烷等有机溶剂提取,用HPLC方法检测。对方法的萃取回收率、线性、精密度等进行考察。结果方法选用二氯甲烷作为萃取溶剂,萃取回收率大于60%。血液中尼可刹米的在0.5~100μg/ml范围内线性良好,R2为0.9993;脑脊液中尼可刹米的线性范围为0.1~100μg/ml,R2为0.9996,最低检出限是5ng(S/N≥3)。检测血液和脑脊液中的尼可刹米方法的精密度均小于6%。结论所建方法准确、简便、灵敏度高,适用于法医毒物分析和临床药物分析。     

离子液体分散液相微萃取-HPLC检测血浆中溴敌隆

目的建立离子液体分散液相微萃取-HPLC检测血浆中溴敌隆的方法。方法以1-己基-3-甲基咪唑六氟磷酸盐([HMIM]PF6)为萃取剂,甲醇为分散剂,提取血浆中的溴敌隆,用HPLC分析其含量;考察了萃取剂和分散剂体积、样品pH值、NaCl浓度、萃取时间和离心时间等因素对萃取效率的影响。结果优化的溴敌隆分散液相微萃取操作条件为:萃取剂[HMIM]PF650μL,分散剂甲醇100μL,样品pH值5.0,萃取时间5min,离心时间8 min。方法的线性范围:0.01～5.0μg/mL,检测限:1.1 ng/mL(S/N3)。该法低、中、高浓度的平均加标回收率分别为76.4%,82.6%,92.1%,RSD分别为4.17%,2.99%,1.67%(n=6)。结论本方法检测血浆中的溴敌隆,简便快速、准确实用,满足中毒检测及临床诊断治疗的需要。     

Absorption of ignitable liquids into polyethylene/polyvinylidine dichloride bags

Clear plastic bags are often used for the collection, sampling and storage of ignitable liquid evidence. They are popular because they are easy to store. transport and are inexpensive. Cryovac and Globus brand polyethylene/polyvinylidine dichloride bags were tested for suitability in storing ignitable liquid evidence. Standards of diesel, kerosene and gasoline were placed in the bags and sampled by passive headspace adsorption. The bags were then heated to determine if absorbed components of the standards could be released upon heating. Recovered extracts were analyzed by GC and GCMS. These bags were found to absorb components of diesel, kerosene, and gasoline. and were also found to produce interfering by-products that obstruct the chromatographic results. Evidence containers need to be tested to ensure that low levels of ignitable liquids are not missed.     

A solid-phase microextraction method for the detection of ignitable liquids in fire debris

A solid-phase microextraction (SPME) procedure involving direct contact between the SPME fibers and the solid matrix and subsequent gas chromatography/mass spectrometric analysis for the detection of accelerants in fire debris is described. The extraction performances of six fibers (100 mum polydimethylsiloxane, 65 mum polydimethylsiloxane-divinylbenzene, 85 mum polyacrylate, 85 mum carboxen-polydimethylsiloxane, 70 mum Carbowax-divinylbenzene, and 50/30 mum divinylbenzene-Carboxen-polydimethylsiloxane) were investigated by directly immersing the fibers into gasoline, kerosene, and diesel fuel. For simulated fire debris, in the direct contact extraction method, the SPME fiber was kept in contact with the fire debris matrix during extraction by penetrating plastic bags wrapping the sample. This method gave comparable results to the headspace SPME method in the extraction of gasoline and kerosene, and gave an improved recovery of low-volatile components in the extraction of diesel fuel from fire debris. The results demonstrate that this procedure is suitable as a simple and rapid screening method for detecting ignitable liquids in fire debris packed in plastic bags.     

Dermal absorption of kerosene components in rats and the influence of its amount and area of exposure

The influences of amount and area of dermal exposure to kerosene upon the levels of kerosene components in biological samples were examined in vivo and in vitro. Thirty-two rats were randomly divided into four groups and exposed to kerosene through the abdominal skin for 2h. The amounts (soaked in cotton) and area of kerosene exposed were 1 ml/4 cm(2) in Group I, 4 ml/4 cm(2) in Group II, 4 ml/16 cm(2) in Group III and 16 ml/64 cm(2) in Group IV. Before, then 5, 10, 20, 30, 45, 60, 90 and 120 min after exposure, 0.5 ml of blood was collected. Solid tissue samples, including the exposed skin area, were harvested at 120 min. Kerosene components were analyzed by gas chromatography/mass spectrometry. Trimethylbenzens (TMBs) that are easily absorbed kerosene components, appeared at 5-20 min. The time course changes in TMB levels in blood were significantly different between Groups I and II or Groups I and III, and almost identical between Groups II and III. Similar trends were observed in tissue samples at 120 min. High concentrations of aliphatic hydrocarbons (AHCs) were detected in the exposed skin and the AHC levels were dependent on the amount of kerosene exposed per unit area. These results suggest that (1) dermal absorption of kerosene occurs soon after dermal exposure started, (2) absorption of TMBs is influenced by the total amount of kerosene rather than area of exposure, and (3) AHCs remaining in the skin at significant levels are influenced by the amount of kerosene per unit area exposed.     

应用SPME—GC／MS／PFPD技术测定烃类及硫化物标记物鉴别汽油、煤油、柴油燃烧残留物

目的利用汽油、煤油、柴油等助燃剂中特殊的硫化合物类标记物,建立一种新型的火场助燃剂残留物分析方法。方法应用固相微萃取气质联用一脉冲火焰光度检测器（SPMBGC／MS／PFPD）技术同步测定烃类、芳香烃类及硫化合物类。结果确定了13种特征硫化合物。质谱烃类数据和PFPD硫化合物数据稳定,RSD％值分别≤0．75和≤1．29。结论该方法能对各种纵火现场助燃剂微量燃烧残留物进行有效鉴别。     

The detection and analysis of ignitable liquid residues extracted from human skin using SPME/GC

A simple, fast, inexpensive, and sensitive technique for the detection and identification of flammable or combustible liquid residues on the skin of arson suspects is presented. The use of solid phase microextraction (SPME) for the analysis of ignitable liquid residues has been demonstrated and it is shown in this work that this technique is effective in extracting these liquid residues at extremely low quantities. Microliter quantities of controlled spikes of gasoline, diesel fuel, and charcoal lighter fluid were deposited on the hands of a volunteer and extracted after several time intervals. The SPME technique can recover very small amounts of liquid deposits on skin up to 3.5 h after exposure, depending on the class of the ignitable liquid residue used.     

Intratracheal gas analysis for volatile substances by gas chromatography/mass spectrometry--application to forensic autopsies

Intratracheal gas analysis was carried out by gas chromatography/mass spectrometry (GC/MS) in 20 burned body cases (13 males and 7 females). Volatile aromatic and aliphatic hydrocarbons were detected by GC/MS using a GS-Q column with the intratracheal gas as well as the blood in 19 cases. The characteristic patterns of mass chromatograms for gasoline, kerosene (gas oil), and liquid petroleum gas could be differentiated from each other using the intratracheal gas. The burned body in one case showed no presence of volatile substances in the intratracheal gas, nor intratracheal soot, although high concentrations (1 microg/g and more) of volatile substances were detected on the clothes. The victim also had normal CO-Hb concentrations (0.1 to 0.2%) in the heart blood. The results of intratracheal gas analysis were consistent with signs of the vital reaction. In conclusion, intratracheal gas analysis provides a supportive method for diagnosing the cause of death in burned bodies, and yields for at least 48 hours valuable information on volatile hydrocarbons (being detected in deliberate or accidental fire cases) to which the body had been exposed just before death.     

Compositional analysis for identification of arson accelerants by electron ionization Fourier transform ion cyclotron resonance high-resolution mass spectrometry

Elemental compositions of each of 100 to 500 different constituents (i.e., every peak in a mass-to-charge ratio range, 50 < m/z < 300) of lighter fluid, kerosene, turpatine, gasoline, diesel fuel, and two brands of mineral spirits (and their weathered analogs) make possible direct identification of each accelerant in a experimental fire, based on electron ionization 6.0 Tesla Fourier transform ion cyclotron resonance (EI FT-ICR) ultrahigh resolution mass spectrometry. Septum injection of as little as 500 nL of accelerant into an all-glass heated inlet system yields definitive elemental compositions (molecular formulas) based on accurate (< +/-1 ppm average error) mass measurement alone. Extraction and EI FT-ICR mass analysis of fire debris from a controlled burn of a couch with simple (lighter fluid) and complex (turpatine) ignitable liquid yielded dozens of elemental compositions serving as a unique "fingerprint" for each petroleum product, despite the presence of up to 249 additional extracted matrix and pyrolysis components. Forty-five of 56 lighter fluid constituents and 126 of 133 turpatine constituents (not counting 13C-containing species) were identified in the debris from a fire staged for each respective accelerant.